Crossing protective system



May 8, 1940.

s. M. NAMPA CROSSING PROTECTIVE SYSTEM Filed Nov. so, 1936' v 7 ii: I I lil m May 28, 1940. MP 2,202,316

CROSSING PROTECTIVE SYSTEM Filed NOV. 30, 1936 9 Sheets-Sheet 2 INVENTOR.

17 /;a M4 5a 20 M A a 127 E- BY Ma A! I 4 9! 2 ATTORNEYS.

May 28, 1940.

s. M. NAMPA 2,202316 CROSSING PROTECTIVE SYSTEM Filed Nov. so, 1936 9 Sheets-Sheet s 1: 56 llll I so #4 Aw 68 r 450 INVENTOR.

70 58120 7. Nawfa. A BY ATTORNEY-S.

May 28, 1940. s, M, NAMPA caossme RROTECTIVE SYSTEM FiledvNov. 30, 1936 9 Sheets-Sheet 4 INVENTOR.

/ 9%."; 4 ATTORNEYS.

SzzZa 7. N4 BY s. M. NAMPA 2,202,316

CROSSING PROTECTIVE SYSTEM Filed Nov. so, 1936 9 Sheets-Sheet 5 INVENTOR.

9" I ATTORNEYS.

May 28,1940." AMP 2,202,316

CROSSING PROTECTiVE SYSTEM Filed Nov. 30, 1936 9 Sheets-Sheet 6 E-J-E- 3,34 V v INVENTOR.

Sula) 0 dm7d. BY

' I? f ATI RNEY5- May 28, 1940. 5 M MP 2,202,316

CROSSING PROTECTIVE SYSTEM Filed Nov. 30, 1936 9 Sheets-Sheet 7 INVENT OR. Sulq A7. flampd. BY

ATTORNEYS.

May 28, 1940.

s. M. NAMPA 2 2,202,316

CROSSING PROTECTIVE SYSTEM Filed Nov. 30, 1936 9 Sheets-Sheet 8 INVENTOR. Sula A7. Nampq.

A TTORNE Y5- CROSSING PROTECTIVE SYSTEM Filed NOV. 30, 1936 9 Shets-Sheet 9 I INVENTOR. 52([0 M #472 74,

ATTORNEYS.

Patented May 28, 1940 I UNITED STATES PATENT F CROSSING PROTECTIVE SYSTEM Application November 30, 1936, Serial No. 113,410

11 Claims.

The present invention relates to crossing protective devices of the barrier type, that is, of the type in which a retractable and projectable barrier is supported in a pit in a roadway or other area to be protected, and maybe automatically or otherwise projected to a blocking position and retracted therefrom under predetermined operating conditions. r

Objects of the present invention are to provide an improved barrier protective system of the above identified type, so constructed and arranged as to insure proper operation under all conditions, and which may be relatively economically manufactured,- assembled, and installed.

More specific objects of the present invention are to provide a protective system of the above stated character, embodying a plurality of barrier devices, the projecting movements of which are efiected by continuously acting mechanism associated therewith, andthe retracting movements of which are provided by positive driving mechanism associated therewith; to provide such a system in which the projecting movements may be efiected by weight operated mechanism; to provide such a system in which the retracting mechanism embodies crank shaft elements suitably connected to the barrier devices, and eifective to control the rate of the projecting movement; and to provide such a system in'which the connections between the projecting. elements and the barriers, and the connections between the retracting elements and the barriers are resilient.

Further objects of the present invention are to provide a barrier system as above described,

including improved means to enable the retract-.- ing mechanism to apply a positive lifting force to the barriers under certain circumstances; to provide such a system in which the just stated force is applied through one or more cams associated with the barrier crank shafts and disposed to positively force the same upwardly; to

" provide such a system in which the cams are with the bell cranks except during a predetermined initial portion of the barrier projecting movements.

Further objects are to provide such a system embodying improved means for locking the bar- 'riers in projected position; to provide such looking means embodying one or more pivotally mounted arms, responsive to the barrier position, and swingable into and out of locking engagement with the barriers; to provide such a system in which the connectionsbetween the barriers and the retracting mechanism are of a lost motion type, permitting the barriers to be forcibly depressed against the forces of the lifting means, independently of the positions of the retracting elements; to provide such a system embodying snubber mechanism to limit the speed of movement of a barrier.

With the above and other objects in view, .whichapDear in the following description and in the appended claims, preferred but illustrative embodiments of the present invention are shown in the accompanying drawings, throughout the several views'of which'corresponding reference characters are used to designate corresponding parts, and in which:

- Figures 1 and 2, taken together with Figure 2 considered as positioned to the right of Figure l,-comprise; a view in perspective, with certain of the parts broken away, of the crossing barrier of the present invention;

Figure 3 is a fragmentary view in front elevation of the improved barrier, showing the structuralsupporting elements associated therewith;

, FigureBA is a schematic View, illustrating the disposition of barriers at a railroad crossing; Figure 4 is a view in vertical section, taken along the line i4 of Figure 1, showing details of the hinging andbuffer construction;

Figure 5 is a fragmentary view in vertical section, illustrating further details of a bufier shown in Figure 4;

Figure 6 is a view in vertical section, taken along the line 6 -6 of Figure 4, showing further hinging details; I

Figure? is a fragmentary view, partly in sec- 7 tion, taken along the line 1-! of Figure 6;

Figure 8 is a fragmentary view in vertical section taken along the line 8-8 of Figure 4;

Figure 9 is a view in vertical section, taken along the line 9-8 of Figure 1, showing details of a crank connecting arm;

Figure 10'is a fragmentary view in vertical section, taken along'the line llllfi of Fig.1. Figure 10A is a fragmentary view, corresponding to Figure 10, and showing a modified icebreaker construction;

Figure 11 is a view, partly in vertical section, taken along the line iI-ll of Figure 9;

Figure 12 is a view in vertical section, taken along the line i2-|2 of Figure 11, showing details of the locking arm;

Figure 12A is a fragmentary view corresponding to Figure 12 and showing a modified locking construction.

Figure 13 is a view in vertical section, taken along the line l3i3 of Figure 1, showing details of the torsion lifting springs;

Figure la is a view in vertical section, taken along the line l4!4 of Figure 13;

Figure 15 is a View principally in vertical section, taken along the line iii-Hi of Figure 13;

Figure 18 is a fragmentary view in section, taken along the line iii-l6 of Figure 13;

Figure 17 is a fragmentary View in section, taken along the line l'lil of Figure 13;

Figure 18 is a fragmentary View in vertical section taken along the line lt-JB of Figure 15; Figure 19 is a fragmentary view in vertical section, taken along the line l9l9 of Figure 1, showing details of the snubber structure' Figure 20 is a fragmentary View in elevation of a weight actuated embodiment of the present invention; and Figure 21 isa view in vertical section, taken along the line 2l-2l of Figure 20.

General description-Figures 1, 2, 3, and 3A Referring first to Figures 1, 2, 3, and 3A, each barrier device comprises generally a barrier 50 which is projectably and retractably supported in a casing 52, supported upon beams 54 extending transversely thereof, and which are suitably imbedded in a pit formed in the roadway with which the device is associated. Preferably, as shown in the diagrammatic View, Figure 3A, each crossing installation includes at least four of the devices, two thereof being mounted at each side of the protected intersection. Each of the illustrated traihc lanes A and B (Figure 3A) is thus provided with two of the devices, one thereof being at the entering side of the intersectionand the other thereof being at the departing side 'of the intersection. In certain instances, it is found practicable to protect only the entering side. Generally, however, it is found advisable to protect each lane at both the entering and departing sides, 'in order toprevent an oncoming vehicle from avoiding the barrier by swerving out of the regular lane of travel. All barriers at each side of an intersection are connected together for common control by a single drive unit 55 individual to such side.

In Figure 3A also, it is assumed that each device is sufilciently wide to protect its entire associated lane. To accommodate the devices to lanes of greater width, it will be appreciated that the lengths of the individual devices may be increased. Alternatively, the devices may be made in a variety of different lengths, and two or more thereof connected in end to end relation to accommodate roadways of too great a width to be handled conveniently-by a single device per lane. A feature of the present construction is the ready adaptability of the barriers for such end to end duplication, and the adaptability thereof for connection at either end to the driving unit.

As an aid in appreciating the following detailed descriptive matter, the operation as a whole of motor 57 associated with the drive unit at each side of the intersection. Each motor accordingly releases a brake associated therewith and starts, thereby rotating the crank shaft 59 connected thereto, which crank shaft is connected to the barriers 50 through a plurality of connecting arms M. This action permits a plurality of torsion springs 63, associated with each barrier, to force the latter upwardly, during which movement it rotates about the pivotal connection between the rear corner thereof and the casing. After a short initial raising movement, sufficient to bring the warning indicia on the face of the barrier into view, a controller 65 individual to each drive unit interrupts the motor circuit and applies the brake thereof, bringing the barriers to rest in an initial or warning position. After a suitable predetermined interval, determined by suitable timing mechanism, each controller 65 again places the associated motor 5'! in operation, continuing the upward movements of the barriers. At the upper limit position, each motor 5"! is automatically stopped by the associated controller 65. Upon reaching the limit position also, the barriers associated with on-coming lanes are automatically locked in the raised position. The barriers associated with outgoing lanes are preferably not locked, so that they may be depressed to permit movement of vehicles thereover. Preferably, also, the outgoing barriers are lifted to only an intermediate height, limit stops being provided for this purpose.

As the actuating vehicle leaves the intersection, motor 5! isagain started in the original direction and, through the arms 6!, pulls each connected barrier downwardly in a single, continuous movement, to its original position, against the force of the torsion springs 63. Upon reaching the original position, each motor 557 is again brought to rest by the action of the associated controller 65.

Each barrier may thus be broadly characterized as'one which is raised through the influence of the torsion springs associated therewith and 'which is lowered through the force directly apspring during the raising rotation of the drive unit, at any time between the initial movement thereof and the time that the limit position locking mechanism is rendered effective. Snubbers 69 are provided to prevent a too rapid or a too high rise of each barrier following such a depression.

The initial lifting movement of each barrier actuates a limit switch 61 individual to each device, which controls the circuit for usual crossing traffic warning lights.- The barrier control systems are also so' arranged that the barrier movement is accompanied by the actuation of a plurality of lamps Giilocated in" the casing, and which, in conjunction with suitable reflectors, act to illuminate the warning indicia located on the face of each device.- These lights remain lighted in continuously'flashing relation from the time ofinitial actuation thereof until the barrier reaches a corresponding point in its downward or return movement.

The drive units per se and the control systems therefor form the subject matter of the copending application, James lVll. Evans, Serial No. 109,- 941, filed November 9, 1936, and assigned to the assignee of the present application.

The warning light structure for the barriers and the control system therefor form the subject matter of copending application of James M. Evans, Serial No. 108,150, filed October 29, 1936, and assigned to the assignee of the present application.

Certain of the broader aspects of the present construction are disclosed and. claimed in the copending application of William G, Miller, Serial No. 125,081, filed February-10, 1937, and certain of the detailed features disclosed herein are claimed in the copending application of James M. Evans, Serial No. 108,149, filed October 29, 1936, both of which are assigned to the assignee of the present application.

Barrier and casing constructionFigures 1, 2, 3 and 4 Each barrier 56 is preferably formed as a single,

- elongated, shell-like casting, generally triangular in shape in vertical transverse section, the back of which is enclosed to form a part of the roadway when the barrier is in depressed position, and the generally arcuate front of which is enclosed to form an impact portion and a protective skirt portion. The ends are also preferably enclosed to constitute protective skirts. The under side is preferably open to accommodate the operating elements associated with the barrier. Each enclosing end skirt 56 of each barrier 59 lies closely adjacent the associated end 58 of the casing 52, and so acts to prevent dirt and other foreign matter from falling into the casing when the barrier is in the raised position. The forward skirt portion 89 lies closely adjacent the forward, upper edge lip 62 of the casing when the barrier is in raised position and performs a corresponding function. The rectangular dimensions of each barrier 59 and casing 52 are such that in the retracted position, only very small spaces are left around the barrier edges, thus minimizing the entrance of dirt and other foreign matter into the casing.

As described in more detail in the above application, Serial No. 198,159, filed October 29, 1936, the forward face of each barrier is provided with suitable warning indicia, such as the letters RR and the word STOP preferably outlined in refleeting buttons. Cutouts are also provided to receive large lenses B4. The lenses are preferably supplied from light sources individual thereto and illustrated as comprising a pair of lamps 66 disposed at either end of the casing adjacent the base thereof; Light from the lamps [i6 is reflected from a pair of moving reflectors and the lenses 6 which reflectors move in accordance with the movements of the barrier. Thus, a substantially uniform angle of incidence is maintained between the roadway and the light transmitted through the lenses. Preferably, the arrangement is such that the light transmitted from the barrier, is confined within a relatively narrow band. Ac cordingly, as the barrier moves upward as hereinafter described, a driver of an on-coming vehicle is confronted with a substantially continuous band of red or other colored light, extending entirely across the roadway and providing a highly effective warning. H

The impact portion 68 of each barrier is preferably reversely formed, to present an arcuate engaging surface. The arcuate curvature is preferably such that a substantial area is engaged by a tire of a vehicle which engages the barrier. The inclination of the engaging portion 68 in its relation to the heighth of the barrier, is determined in accordance with the disclosure of the copending application of Edward S. Evans, Serial No. 33,037, filed July 25, 1935, now Patent No. 2,075,892 and assigned to the assignee of the present application. As disclosed and claimed in this copending application, by properly relating the heighth and inclination of the engaging face of the barrier, a construction results which, when engaged by a vehicle, forces the front end of the vehicle upwardly with a force suificient to substantially counter-act the forward thrust which would otherwise be given an occupant of the vehicle. Vehicles may thus be stopped by the barriers Without injury to occupants of the vehicles.

Each casing 52, one of which, as previously stated, is individual to each barrier 59, is preferably formed of an elongated rectangular box-like casting, open at the top and at the bottom. and disposed to be supported in the roadway pit upon the previously identified, transversely extending, beams 5%. A plurality of transverse, inverted, channel shaped ribs 10 extend between the forward and rear walls 72 and 14 of each casing, and, in cooperation with the hereinafter more fully described buffers 76 carried thereby, act to support the lower edge of the arcuate front face of the associated barrier when the latter is in the retracted position. The lips 62 and 78, associated with the forward and rear upper edges of each casing 52, cooperate with the supporting masonry 80 in maintaining the upper surface of each casing 52 in a flush relation to the roadway.

Each device, including a barrier 59 and a supporting casing 52, is preferably shipped to the point of installation in a completely assembled condition. A preferred method of erecting the thus previously assembled device consists in providing the pits in the roadway with a masonry footing 82, which forms a substantial and firm support for the beams M, which carry the casing 52. After thus being preliminarily positioned, the masonry 89 may be poured around each casing 52 at the front and rear sidesthereof. In certain instances, it is desirable to form the pit deep enough. to provide a chamber 81 beneath the barrier, to afford access for inspection or repair. In certain other instances, as described hereinafter in more detail, it is desirable to arrange the barriers for access from above.

It will be appreciated that, in operation, crossing barriers of the type in question are subjected to an extremely heavy duty. They are required to successfully withstand the impact forces of vehicles of widely varying weights, and traveling at widely varying speeds, and are required to bring said vehicles to rest without permitting the passage thereof into the protected intersection. Each barrier and casing is accordingly subjected to tremendous impact forces.

The forces involved in the successful operation of a protective device of the kind in question have shown it to be inadvisable to utilize a usual hinging relation between each barrier and its supporting casing. The present construction provides a hinging relation between each barrier and its supporting case which is such that all impact forces applied to a barrier are transmitted directly from the barrier to the supporting walls or ribs of the casing, and are not transmitted through the elements which form the pivotal connection between the casing and the barrier.

Referring particularly to Figures 4, 6, 7, and 8, the rear edge of each barrier 58 is provided along its length with a plurality of spaced bearing bosses 99, provided with suitable bushings 92, and through which pins 9d are passed. Each pin 94, which may and preferably is provided with a suitable lubricant fitting 9t, is journaled in spaced bosses 98 formed at the upper ends of the legs of a spring arm Illil. Each spring arm IE5] is pivotally connected at its lower end to a boss I92 formed in an associated one of the previously mentioned transverse ribs m, by means of a pin Hi l, which passes through the boss m2, and the opposite ends of which are freely received in somewhat elongated slots Iilfi formed in the lower ends of the legs of the spring arm H39. A compression coil spring I 598 is seated between each boss I532 and a pin Hi3, which depends from a cross web H2 formed in each arm I30. Each spring Hi3 thus acts to urge its associated arm upwardly so that the lower ends of the arm slots BBS bear against the under side of the associated pin lilfl. The slots 36, however, permit each arm ms to be depressed somewhat against the force of the compression springs I88. The arms It!) thus act to floatingly vertically support the rear edge of the barrier 50..

A pair of compression springs IE3, associated with each arm I89, act between the back H4 thereof, and the rear casing wall, and serve to continually urge the associated arm it!) in a counter-clockwise direction, as viewed in Figure 4. One end of each spring H3 bears directly against the base of an associated recess IIE formed in the rear casing wall, and the other end thereof is received in a cuplike member I 58, which may be suitably secured to the back lid of the associated arm 56G.

Springs II 3 are opposed by a single compression spring 528, one end of which bears against the inner face of the back ii I 4 of the associated arm I 00, and the outer end of which is fitted over a retaining member i222, which is supported adjacent the web E24 of the U-shaped bracket I26, which is either integrally formed with casing 52 or is suitably secured thereto, with the web I24 thereof spaced inwardly from the rear wall of the casing, and the legs I28 thereof spaced apart sufficiently to receive the associated arm I 09. The position, and hence the initial compression of spring I26 is adjustable by means of an adjusting screw I30, which may be locked in position by a set screw I32. Adjusting screw 53%? is preferably adjusted so that in a free condition the barrier 50 is held by springs I 213 and the opposing springs I I3 in a position such that the rear edge thereof is slightly inwardly spaced from the rear wall of the casing, and the forward face thereof is spaced slightly inwardly from the forward wall of the casing. I

Two additional springs I34 and I36, which act in opposing relation to each other, are provided to resiliently balance or secure the barrier 58 in a predetermined longitudinal position. Bolts I and I37, threaded into the sides of arm I09, pass freely through the legs I28, and are provided with retainers I33 and Isl which seat the outer ends of springs I35 and I36. The other ends of springs I34 and I35 are seated in recesses provided in the legs I28 of the previously mentioned U-shaped bracket member I26.

With the above described arrangement, it will be evident that each barrier 50, supported at a plurality of points along its length, floats vertically of the casing under the restraining influence of the springs I08, floats transversely of the associated casing under the restraining influence of the opposed springs H3 and I20; and floats longitudinally of the casing under the restraining influence of the opposed springs I34 and I36.

In order that forces striking the barrier of suflicient magnitude to overcome the restraining forces of the previously described balancing springs and thus of suflicient magnitude to displace the barrier in the casing, may be transmitted directly between the barrier and the easing, independently of the hinge pins 94 and I04, abutment means are provided to absorb the vertical, transverse and longitudinal components of such forces.

To absorb vertically directed forces, a foot I40 is formed within the barrier 58 adjacent each boss 90 and which, in the free position of the barrier, occupies a position in slightly spaced relation to the upper surface I42 of the associated U-shaped brackets I26. The spacing between foot I40 and the surface M2 is less than the lost motion in the connection between each arm Hill and the 9 associated pins I04. Accordingly, any vertical force of sufficient magnitude to substantially compress the springs Hi8, causes the feet I49 to engage the supporting surfaces M2, so that all of the vertical load transmitted beween the rear edge of the barrier and the casing is thus transmitted directly between the feet M9 and the supporting surfaces I42. Vertical forces directed against the front edge of thebarrier are absorbed by the hereinafter described buffers I6.

Similarly, to absorb any force sufficient to cause the barrier feet to move rearwardly in the casing, or to the right, as viewed in Figure l, the previously mentioned rear edge rib formation 18 of the casing 52 is made sufficiently heavy to form a positive support for the rear edge of the barrier when engaged thereby. Rearwardly directed forces, acting on the barrier, are thus transmitted between the barrier and the casing through the engagement of the rear edge of the barrier with the rear upper lip formation of the casing. To similarly transmit directly to the housing forwardly directed forces, that is, forces tending to cause the barrier to move forwardly within the housing or to the left, as viewed in Figure 4, a plurality of arcuately formed ribs Md are provided in spaced relation along the forward wall of the casing, and which extend toward the rear wall. In the free position of the barrier, the arcuate forward face 68 thereof lies in slightly spaced relation to the ribs I l l. A forward movement of the barrier, against the resistance of the springs I2Il,.however, brings the forward barrier face Bil directly into engagement with the ribs I 24, which constitute a positive limit to such forward motion, and relieves the springs i20 of further load.

Forces acting longitudinally of the barrier, if sufficient to compress one or the other of the springs I34 and B36, brings the ends iiii'of the barrier directly into abutting relation to the ends 58 of the casing, which members thus act to directly transmit such longitudinal forces from the barrier to the casing.

Each of the buffer plates 76, one of which is per platelike portion whichforms a seat, and a cylindrical boss portion I50 formed integrally with the seat portion and extending downwardly therefrom. An elongated opening I52 extends through the boss portion and forms a lost motion connection with a retaining pin I54 which passes therethrough, and the opposite ends of which are supported in openings (not shown) in the opposite sides of the channel shaped transverse rib I9. Each pin I54 therefore acts to loosely prevent displacement of the associated bufier plates I6 from their supporting ribs. The supporting ribs are each provided with recesses or depressions I56 within which the plate portions of the buffers are somewhat loosely received.

The under side of each boss portion I59 rests upon an upper spring retainer I51, preferably of circular construction, and the upper surface of the marginal edge of which bears against a seat I58 provided therefor in the associated rib I9. A compression spring I 50 is seated between each of the upper retaining members I51 and a similarly constructed lower spring retaining member 152, which is supported upon a seat I64 provided therefor in the base of the associated transverse rib I9.

The barrier 59 is provided with an inturned flange I69, which extends throughout the length thereof, and is reinforced at a plurality of spaced points by ribs I58 and by'additional ribs I69. In the retracted position of the barrier, the flange I86 rests upon and is supported by the plurality of bufier plates 79, which floatingly retain the barrier in the position of the parts illustrated in Figure 4 under the influence of the supporting springs I69, Any vertical force acting on the front edge of the barrier, however, and forcing the latter downwardly, initially compresses the springs 59. If the force is of sufficient magnitude, it compresses the springs IBII, sufiiciently to bring the under sides of the plate portions of the buffers I6 into engagement with the bases of the recesses I56 provided therefor in the transverse ribs, which recessesthus form a positive limit to such downward movement and act to transmit such vertical force directly from the barrier to the casing through the ribs III.

A structural feature of importance in connection with the buffer plates and associated spring mechanism is shown in Figure 5. In Figure 5,'

which shows the upper and lower spring retainers I5? and IE2 in section, the lower sp'ring retainer N52 is provided with a drilled opening I10, large enough to freely pass an adjusting stud I72, the threaded end of-which is threadably received in an internally threaded opening I14 provided in the upper spring retainer I51. The base I15 of the transverse rib It is provided with an opening H8 sufficiently large to freely pass the head of the adjusting stud I12. In assembling the parts, the buffer plate I5 is first freely dropped into the recess I5fiprovided therefor in the transverse rib. Thereafter, the pin I54 is As a preliminary to inserting" inserted in place. the spring I69, the adjusting stud is turned into the opening We sufficiently far to compress the spring and bring the two spring retainers i5"! and 52 sufficiently close to eachother that the assembly comprising the spring and the two retainers may be freely slipped between the base of the buffer plate and the upper surface of the portion H6. The final assembly step may consist in withdrawing the adjusting stud I12 sufficiently far to permit the spring I60 to expand and force the lower retainers against the portion I16 and force the upper retainers in the seat I58.

Retracting mechanism, including crank shaft and connecting armsice breakers and locking arms -li igures 1, 2, 9, 10, 11, 12

As previously stated, in a general way, each i barrier 59 is provided with a crankshaft 59 which extends longitudinally therethrough, and has a lost motion connection with each, of a plurality of arms SI, which are respectively pivotally connected to the upper surface of the barrier. The crank shafts are actuated by the drive units and onecomplete revolution of eachthereof is effective to permit one complete raising movement under the influence of the previously mentioned torsion springs 63 and a complete retracting movement, approximately 180 degrees of travel being involved in each of the-projecting and retracting movements. The lost motion connection between each crank shaft and its associated connecting arm permits the barrier to be retracted against the force of the torsion springs,

independently of the crank shaft movement. It

also permits the barrier movement to be interrupted at any point in its travel, independently of the crank shaft movement, so that the upper limit of travel of a barrier may be determined independently of the throw of the associated crank shaft. During travel of the crank shaft in the lowering 180 degrees of movement, however, the offsets positively engage the connecting arms and correspondingly positively effect a barrier retracting movement;

As shown generally in Figures 1 and 2, and in greater detail in Figures 9 and 11, the crank shaft 59 associated with each barrier 50 is rotatably journaled within the associated casing in bearings formed by pillow blocks I89, which are supported upon the transverse ribs id and which may be secured thereto in any suitable manner. As best shown in Figure 11, each shaft 59 is formed insections 59a and 5%, connected together by members I82 which constitute offsets, and which are keyed by keys I8I to the shaft sections. The number of ofisets depends of course upon the number of arms fiI desired. In the illustrated arrangement, two connecting arms 6| are provided. The left hand end of crank shaft 59, as viewed .in Figure 1, extends slightly outwardly of the end of the casing 52, which end is provided with a suitable opening to accommodate the crank shaft, and is coupled to the shaft of the drive unit 55 by a conventional flexible coupling I86. The other end of the crank shaft is adapted for corresponding connection to the crank shaft of an immediately adjacent barrier. I

Referring particularly to Figures 9 and 11, each arm BI comprises a generally U-shaped member, the free ends of the legs I88 and I90 of which are connected together by a stud 592, and are maintained in substantially parallel spaced relation by a combined spacing and bearing block I94, the curvature of the inner face of which corresponds to the curvature of the shaft portion I96 associated with the offset IBZ-in the tion receives a compression spring i538, one end of which is seated against the base of the U- shaped member and the other end of which bears against a retaining plate 2%. Plate 200 is threadably secured to the free end of a stud 292, which freely passes through an opening provided therefor in the base of the U-shaped membar, and is provided with a head 29 Each head End is pivotally connected by a pin 2% to a clevis Z38 either formed integrally with or suitably rigidly secured to the under side of the barrier 58.

The parts are shown in Figures 9 and 11 in the projected position, in which the offsets l82 of the crank shafts are in their extreme positions of upward barrier movement. As will be evident, rotation of crank shaft 59 in either a clockwise or a counterclockwise direction from the position shown in Figure 9, is effective to lower the barrier 58 through the connections between arm El and the crank shaft 59, the lowering force being transmitted through the compression springs 593. A resilient connection is thus provided between the crank shaft and the barrier. The lowering movement is also opposed by the torsion springs E53 as hereinafter more fully described.

As will also be appreciated the crank shaft position corresponding to the barrier retracted position is disposed approximately 180 degrees from the position illustrated in Figure 9. Assuming the barrier to be in the lower position, a crank shaft rotation in either direction from the retracted position is effective to permit a barrier raising movement under the force applied thereto through the torsion springs 63, as hereinafter described. Through the lost motion connection between the crankshaft portion 596 and each arm 65, the crank shaft 59 is effective to limit the rate of rise of the barrier 56, but is'ineffective to cause a rising movement.

As will be further appreciated, the provision of a structure in which a complete raising and lowering cycle involves 360 degrees of crank shaft movement, avoids the necessity of providing reversing mechanism for the driving motor asso ciated with the driving unit, and correspondingly simplifies the control and arrangement thereof.

In instances Where the device remains in the retracted position for long periods of time, and under severe weather conditions, it may be expected that more or less ice will accumulate between the barrier and the casing therefor which may oppose the projecting movement of the barrier with a force in excess of the force applied thereto through the torsion springs 63. In the present construction, the arrangement is such that to initially break loose the barrier, the lifting force applied to the barrier through the torsion spring 63 is supplemented by the driving force of the drive unit. Referring particularly to Figures 1, 2, and 10, a pair of cams 21s are suitably keyed by keys 2l2 to the crank shaft 59 in position for cooperative engagement with seats 2M formed at the bases of the stiffening ribs E69.

Each cam 2H3 is provided with a major peripheral portion a of uniform radius, such as to lie in slightly spaced relation to the associated foot 2M when the latter is lowered. The portion 1), which represents an angle of between 40 and is of progressively increasing radius. In the fully retracted position of the barrier, each foot 2M lies in spaced relation to portion a. After a cam shaft movement of a few degrees, for example, 15 to 20, each foot 2| 4 is engaged by the periphery of the associated cam at the low end of portion b. The parts are shown in Fig ure 10 with the foot 2M in engagement with the cam portion of maximum radius, which represents the position attained by the parts after between and 70of crankshaft travei.

In normal operation, in which the forces of the torsion springs 63 are sufllcient to lift the barrier, the barrier lifting movements carry the seats 2 it away from the associated cams. In instances, however, where the torsion spring forces are insufiicient to lift the barrier, the seats 2M may remain in engagement with the associated came during all or part of the 40 to 50 of crankshaft travel, represented by the angular displacement between the limits of cam portion 2;. In such instances, the cams, due to their progressively increasing radius, apply a positive upward force to the feet 214 which of course supplement the forces of the torsion springs and positively break loose the barrier. It will be appreciated that, when the thus combined forces finally overcome the resistance to motion of the barrier, the barrier will then rise to the normal position corresponding to the then angular position of the crankshaft. It will be appreciated, also, that the total change in radius of the cam 2E6, as well as the angular displacement between the points of minimum and maximum radius of the portion b thereof of increasing radius, depends upon operating conditions and may, in certain instances, be less than the described displacement, and in other instances, may be more than the described displacement.

In the modified embodiment of Figure 10A, a bell crank 2 is suitably pivoted upon a trunnion 2L3, in a position to brim one end thereof in the path of the lower edge I66 of the barrier and to bring the other end thereof in the path of a cam 2 l5 suitably keyed to the shaft 59 for rotation thereby. The relation of parts is preferably such that in the barrier retracted position bell crank 2 is slightly spaced from the base 163 and so does not interfere with resilient floating movements thereof. A short initial rotation of shaft 59 and cam 2l5 brings arm 2H into positive lifting relation to base led, and continued rotation of shaft 59 forcibly moves the barrier upwardly. After a predetermined lifting movement of the barrier, proportioned to insure the breaking loose thereof, the cam 2i5 moves be yond the arm 2| l, permitting it to pivot relatively freely, and rendering it ineffective to interfere with a depressing movement of the barrier. Cam 2l5 and arm 2 are thus effective to cooperate only during a certain initial portion of an operating cycle.

As stated in the foregoing general description of operation of the device, the barriers associated with the oncoming lanes of travel are arranged to be positively locked in the fully raised positions by locking mechanism which, while ineffective during the initial raising movements of the barrier, is rendered effective as the barrier reaches its maximum height. It is preferred, however, that the barriers associated with the outgoing traflic lanes be arranged so that they may be depressed at any time, so that vehicles trapped between the incoming and outgoing barriers may pass over the outgoing barriers Without substantial obstruction. In accordance with the present application, the locking mechanism for the oncoming barriers is directly controlled by the cam shaft associated with each barrier.

Referring particularly to Figs. 1, 2, 11 and 12,

a pair of arms 228 and 222 are pivotally supported within each casing 51 by pins 224 and 226, which in turn are journaled in clevices 228 and 230, which may be formed integrally with or rigidly secured to the flanges of the transverse ribs 18. Both the arms 222 and 222 and the elements directly associated therewith are the same and a description of one will serve for both.

Referring particularly to Figures 11 and 12, the arm 228 is of bell crank formation, one arm thereof being provided. with a roller 232, disposed to continuously engage the periphery of a cam 23 which is keyed by a key 236 to the cam shaft 59. The cam 23 is of uniform radius throughout substantially its periphery, but is provided with a portion 238 of reduced radiuswhich registers with the rollers 232 at the angular position of the cam shaft 59 corresponding to the fully projected position of the barrier.

The arm of bell crank 22!], which carries the roller 232, is also provided with a seat 248, against which one end of a compression spring 242 bears. The other end of the compression spring 242 is secured over a boss 24 1 formed on a rearwardly extending projection of the clevis 228. Spring 222 thus continuously urges bell crank 220 in a counterclockwise direction, as viewed in Figure 12. Except when the barrier is in the fully projected position, the portion of maximum radius of cam 234 engages roller 232 and thus retains the end 246 of bell crank 228 in a position to the right of that shown in Figure 12, in which it is inwardly spaced from the face 62 of the barrier 511. As the barrier reaches its fully projected position, however, the seat 248 provided for cooperation with the end 246 of the bell crank passes above such end. At this time also the cam portion 238 of reduced radius registers with the roller 232, permitting the bell crank 22K) to be swung in a counterclockwise direction under the influence of spring 242, to the looking position shown in Figure 12, in which position, it lies directly below the barrier portion 248, and forms a positive block against downward barrier movement.

As soon as a barrier retracting movement is begun by the crank shaft 59, roller 232 is engaged by the cam portion of maximum radius, and is thereby forcibly moved to swing the bell crank 228 out of locking engagement with the face of the barrier. The very short interval of cam shaft movement which is thus necessary before the barrier is released by the bell cranks 222 and 222, is readily absorbed by the previously described springs Hi8 associated with the retracting arms. 61.

As described generally above, it is desirable to permit the barriers associated with outgoing lanes of travel to be depressed at any time. Accordingly, it is preferred to omit the just described locking mechanism from the outgoing barriers. Moreover, as described hereinafter, it is preferred to provide mechanism to limit the travel of the outgoing barriers to an intermediate height. This limiting mechanism is preferably directly associated'with the torsion springs and is described in connection therewith.

In the modified arrangement of Figure 12A, each lifting arm 22! is pivoted upon a trunnion 223 and a spring 2"5 is connected between the arm and the rear face of the barrier to continually urge the same in a clockwise direction to a position out of the path of the foot 248 formed in the barrier. Each arm is provided with a cam nose 221 disposed for engagement by a cam 229 a suitably keyed .to the crank shaft 59. During all portions of the crank shaft travel, except a limited portion, corresponding to the fully projected position of the barrier, a low portion of cam 229 is opposite the nose 221, permitting each arm' 22! to occupy a retracted position. As the barrier I reaches a fully projected position, however, the

high point of the cam 229 engages the nose 221 and forcibly moves the associated arm 22I to the position shown in Figure 12A. The initial retracting movement of the crank shaft 58 moves the cam 22%] away from the nose221, permitting the arm 22! to be retracted. As in the arrangement of Figure 12, the resilient connection between the retracting arms 6l and the barrier (Figure 11) permits the barrier to remain in the fully projected position until the crank shaft 59 has rotated far enough to release the locking arms.

Torsion spring lifting mechanism and travel Zimztz'ng mechanismFigs. 1, 2, 13, 14, 15, 16, 17 and 18 Referring particularly to Figures 1, 2, and 13 through 18, two of the torsion springs 63 are shown as connected between the barrier 58 and the casing 52 for forcibly projecting the barrier to the raised position. The construction and arrangement of bothof the springs 63 is the same, so that the description of one will serve for both. It will be understood also that, in a broad sense, a greater number or a lesser number of the springs may be utilized.

Considering particularly the left hand spring 63 of Fig. 15, the right hand end thereof is rotatably supported upon a hub 268 shown as formed integrally with the reduced rearward portion 262 of one of the ribs 18 (Figure 1). The left hand end of the just mentioned spring 63 is rotatably supported on a hub 264 which forms part of a generally triangularly shaped lifting bracket designated as a whole as 268. The hub 26 i is rotatably journalled upon a trunnion 268 'which is shown as formed integrally with a bracket 210 which is rigidly secured as by the studs 212 to the rear wall 14 of the casing 52. Certainof the studs 212 also support a spring protective apron 213.

The end 216 of spring 63 is connected to the rear wall 14 of casing 52 by a link 218 of adjustable length. One end of the link 218 is provided with the loop 280 which passes over the free end of the spring, and the other end of the link 218 is threaded for cooperation with an adjusting nut 282, The adjusting nut 282 is provided with a tubular shank portion 284, of sufficient length to extend all of the way through the opening 286 formed in the base of the casing, and so protects the threads of the stud 218. The head of the nut 282, as it will be appreciated, is sufiiciently large to have a bearing engagement with the rim of the opening 286.

The back 298 of the triangular lifting bracket 266 is of channel formation, and the upper left hand corner thereof, as viewed in Figure 13, forms a clevis 292, in'which a pin 29 i is journaled,.which pin forms a pivotal connection between the associated lifting arm 296 and the lifting bracket 266. The channel formation of the back 290 also forms a clevis which supports a pin 298, over which the remaining free end 380 of the associated spring 63 is hooked. Preferably, and as illustrated, the just mentioned clevis portion of each lifting bracket 286 is provided with additional cutouts, such as 382, which may in certain instances be provided'with pins to Each arm 2%, which forms a connection between the lifting bracket 266 and the barrier, is of a link formation and comprises a boss Sill formed integrally at one end thereof for cooperation with the previously mentioned connecting pin 294, and a second boss 312, resiliently connected to the other end of the arm. The boss 312 is connected by a pin 3161 to a clevis 316 provided therefor in the barrier 50. The shank MB of each boss 312 is slidably received in an opening 320 provided therefor in the end of the arm 2%. A compression spring 322 surrounds each shank 3H3, and is seated between an adjustable nut 32 i carried by the latter, and the end of the arm 296. The nut 32d is provided with ears 325 which protrude from either side of the arm 2% and prevent turning thereof. The upper end of each arm 2% abuts the lower surface of the connecting boss 3l2, so that a positive driving connection is provided between each lifting bracket 2% and the barrier 50.

As will be appreciated, each retracting movement of the barrier 56 under the influence of the crank shaft 59 and the associated connecting arms 6i, as previously described, forces the lifting arms 2% downwardly, correspondingly rotating the lifting brackets 266 in a counterclockwise direction, as viewed in Figure 13, and winding up the torsional springs 63 to thereby load the springs. On the other hand, rotation of crank shaft 59 throughout the lifting part of its travel relieves the downward force on the barrier, and permits the torsion springs 83 to unwind under the influence of the previously applied stress, forcing the lifting brackets 266 in a clockwise di-- rection, as viewed in Figure 13, and correspond,- ingly forcing the arms 2% and barrier 50 in the upward direction. The resilient connection between the lifting arms 286 and the bosses 312 associated therewith is useful in preventing sudden jars or impacts against the barrier 50 when in a raised position, from being transmitted directly to the lifting brackets 265. This resilient connection, however, is of particular value where it is desired to provide means for positively limiting the rotation of the lifting brackets 26%, as where it is desired to limit the lifting movement of the barriers to a point lower than would be permitted by the travel of the crank shaft 59 and connecting arms 61.

In accordance with the present construction, this supplemental upward movement limiting mechanism is applied to the barriers associated with the outgoing lanes of travel, in order to limit the travel thereof to an intermediate height. This limiting mechanism may, however, be applied to the barriers associated with the oncoming lanes of travel, and so adjusted as to permit the barriers to rise to the full height.

Referring particularly to Figure 14, a relatively heavy U-shaped member 330 is associated with each torsional spring 63. The flanges of each member 330 are connected to associated ones of the transverse ribs 70 by studs 332. Preferably also at least one of the flanges associated with each U-shaped bracket is turned over, as indicated at 334, to cooperate with the base of the associated transverse rib iii and supplement the securing effect of the studs 332. The web 336 of each U-shaped member 339 is disposed for engagement by the portion 30% of the associated lifting bracket 26$ when the latter has rotated to the desired degree, and so forms' a positive limit to further movement thereof. It will be evident that the stop members 330 may be adjusted to limit the travel of the associated barrier to any desired degree. ciation with the outgoing barriers, the member 330 limits the rise thereof to approximately two thirds the rise of the barriers associated with the on-coming lanes of travel.

After a barriers raising movement has been stopped by the stop member 330, any impact or external force applied thereto, tending to cause a further upward movement thereof, is absorbed by the resilient connections between the lifting arms 2% and the associated bosses 3E2 provided by springs 322.

As will be appreciated, the pins 2% associated with arms 6!, and the pins 3M associated with arms 296, are readily removable, to thereby disconnect the barrier 58 from the crank shaft 59 and from the torsion spring mechanism, and permit it to be freely rotated to a position to afford ready access to the interior of the structure from above. To afford access to the pins 206 and 3M when the barriers are retracted, a plurality of hand openings 3l5, closable by removable plates 3 I 1, are preferably provided at appropriate points in the barrier upper surface (Fig. 13).

snubber mechanismFigures 1 and 19 In practice, the projecting movements of the barriers are usually begun when the train 'or other vehicle, the approach of which may be relied upon to actuate the barriers, is a substantial distance away from the crossing to be protected. This initial movement may be expected to occur at a time when highway Vehicles are too close to the barriers to permit a normal stop thereof.- To enable such vehicles to pass over the partially raised barriers, the previously described provisions for depressing the barriers against the forces of the torsional lifting springs, and independently of the angular positions of the barrier crank shafts, is very desirable if not essential. Similarly, it may occur from time to time that a vehicle will be trapped between the barriers at either side of an intersection or crossing and in such instances, it is desirable that the barrier construction permit such trapped vehicle to depress the barriers and pass thereover without substantial obstruction.

While it is desirable, under the conditions above mentioned, that vehicles be able to depress the barriers rapidly and without a too great resisting force therefrom, it is equally desirable to retard the return movements to the raised positions of the barriers, after being depressed. In the absence of a retarding mechanism, substantial injury to the under frame portions of the depressing vehicles may occur.

With the above considerations in mind, a feature of the present construction resides in the association with the barrier of snubber or motion checking mechanism, so connected thereto as to permit a free and unimpeded depressing move- Preferably, in assoment, but to limit the return or raising movement of the barriers to a predetermined value. This predetermined rate of return movement preferably is not greatly in excess of the normal rate of rise as provided by the barrier crank shaft in the normal raising motion of the barriers. Preferably, the snubber is connected directly between each barrier and the associated casing, although, in a broad sense, other relationships are practical.

In the broader aspects of the present invention, the snubber mechanism may be constructed in various ways, but a construction which is preferred is shown in Figure 19 as comprising a fluid pressure device 381, the cylinder member 383 of which is suitably pivotally connected to the base of the barrier casing 52 and the piston rod 385 of which is correspondingly pivotally connected to the under side of the barrier 50. The cylinder 383 is preferably substantially filled with a suitable fluid such as oil and communication between the cylinder portions on opposite sides of the piston 38? is afforded by a connecting line 389. Line 389 communicates with the upper end of cylinder 383 through an adjustable needle valve 391 and a check valve 393. Similar communication between the line 389 and the lower end of cylinder 383 is afforded by an adjustable needle valve 395 and a check valve 391. The check. valves 393 and 391 are arranged to open in response toa pressure tending to permit flow therethrough into the cylinder, but to close and prevent a flow therethrough out of the cylinder into the line 339.

With the just described arrangementit will beappreciated that during a projecting movement of the barrier 50, the piston 38! moves upwardly in the cylinder 383, causing the fluid to discharge from the upper part of the cylinder and flow through the line 385 into the lower portion of cylinder. In this instance, the check valve 393 occupies closed position and the valve 391 occupies an open position. The rate-of flow and consequently the rate of movement of thebarrier 50 is thus determined by the adjustment of the needle valve 39!. During reverse movement, on the other hand, the check Valve 393 is open and the check valve 38'! is closed, the rate of downward movement of the barrier accordingly being limited by the adjustment of the needle valve 395. The rates of raising and lowering movements as controlled by the snubbber 38! may therefore be independently adjusted by independently adjusting the needle valves 39land 395, so as to afford either an unimpeded movement in the retracting directionaccompanied by an impeded movement in the projecting direction, or so as to afford a desired impedance in both directions.

Summary of operation as a whole Summarizing the operation of the system as a whole, all of the barriers at protective crossings normally occupy the retractedpositions' in which the upper barrier surfaces lie flush with the supporting roadway and act as continuations thereof, and in which positions they are held by brakes associated with the drive units. In response to the approach of a train or other vehicle to the crossing to be protected, the motor of thedrive unit 55, one of which is provided at each side of the crossing, starts in operation, initiating a projecting-movement of the barriers connected. thereto. The projecting movement occurs due to the-force directly applied to the barriers through torsion springs 63 individual thereto, but at arate determined by the rate of angular movement of the crank shaft 59 of the barriers. In the event that the lifting forces applied to the barriers through the torsion springs are-in- 5 effective to cause an upward movement thereof, asin instances where ice has collected within the barriers the ice breaking cams 21 8 carried by the crank shafts supply positive lifting forcesto the barriers through the cooperating feet 2M 10 provided on the barrier ribs.

When the barriers reach an intermediate height, which may be called a warning height, the controller 55 associated with each drive unit 55, automatically brings the associated motor 51 -16 to rest, correspondingly stopping the barriers connected thereto. The brake elements associated with each drive motor 51 retain the barriers in positions of rest against the lifting forces of the torsion springs. At the expiration of a predeterminedinterval, determined by the timing mechanism associated with the controller 65, each motor fi'i is again automatically started and permitsthe barrier projecting movement tobe continued to a limit position under the influence of the torsion springs 63. The barriers associated with the on coming traflic lanes are permitted to continue to a maximum projected height, in which position they tified maximum height, this interruption being provided by the stopping members 330, which engage the lifting bracket 266 associated with the torsionsprings 63. i

The on-coming and outgoing barriers thus ooare automatically locked against downward .430

cupy the last mentioned projected. positions 4 thereof as long as the vehicle which initiated their operation remains within a predetermined block associated with the intersection. As soon as the actuating vehicle passes beyond such block,

opposite sides of the intersection areagain placed in operation, rotating in the same direction, and act through the arms 6! associated with the crank shafts 59, to forcibly retract the barriers the motors 51 associated with thebarriers at the 545 against the forces of the torsion springs 63, 5

When the barriers reach the original-retracted positions, the motors 51 are again stopped and the brake elements thereof automatically. applied, and so retain the barriers in the retracted position against the forces of the torsion springs 63, 5

As an incident to the actuation of the barriers,

the warning light systems associated therewith are automatically placed in operation in accordance with the disclosure ofthe previously identified app1ication, Serial No. 198,150 filed October,

29, 1936, and serve to provide an effective warning of the barrier action.

The lost motion connections between each crank shaft lifting arm 6! and the associated sion springs ,63 at any stage in the movement thereof, and permit the oncoming barriers to be depressed'except at such times as thelocking depressing movements of the barriers are unimpeded by the snubber mechanism, but the return movements thereof are maintained at a low rate, commensurate with the normal rate of rise crank shaft 59 permit the outgoing barriers to be ag [forcibly depressed against the forces of the t'or- I arms 220 'and222 are in locking position. They",

thereof. Vehicles too close to the barriers to permit a normal stop thereof at the time the upward .movement thereof is begun, as well as vehicles trapped between the barriers, are permitted to pass thereover without substantial obstruction.

In View of the resilient floating connections between each barrier 50 and the associated casing, provided by the springs E98, H3, H20, and I34 and I355, as well as by the buffer plates 76, each barrier 50 is normally supported in slightly spaced relation from the rear, front and end walls of the associated casing. The just identified springs also resiliently oppose any vertical, transverse, or longitudinal impact forces to which a barrier is subjected. In the event such forces are of sufficient magnitude to overcome the spring resisting forces and cause substantial movements of the barriers within the casings, the barriers are brought into engagement with abutments provided in the associated casings, and such forces are therefore transmitted through such abutments directly between the barriers and the casings.

Modified weight operated barrier lifting mechanism-Fzgures 20 and 21 In the arrangement shown in Figures 20 and 21, the torsion springs 53, described with reference to the preceding figures, are replaced by a plurality of weights 388, suitably and removably carried by abar 382, which extends longitudinally of the barrier 50a. The cross bar 382 is supported adjacent each end by vertical links 384, and is positioned between a stop 3% on each arm and a securing nut 388 thereon, by opposed compression springs 390.

The upper end of each connecting link 384 is formed as a clevis 392, by which, through a pin 394, it is pivotally connected to one arm of a centrally pivoted lifting member 398. Each lifting member 395 is pivotally connected at an intermediate point thereof, by a pin 398, to a bracket which is suitably rigidly secured to the rear wall of the casing 52a. The other end of each arm 3% is connected through a pivotal link 402'to the barrier a.

With this construction, it will be appreciated that the weights 380 apply a continuously acting lifting force to the barrier Elia, in a manner which, in a broad sense, is the equivalent ofthe lifting force applied thereto by the previously described torsion springs 63. In the operation of the embodiments of Figures 20 and 21, accordingly, rotation of the crank shaft 59a, which is constructed and. arranged in the manner described with reference to the preceding figures, and is correspondingly associated with the barrier 50c and the retracting arm (ila, permits the barrier to be lifted by the force applied thereto by the weights 380 in substantially the manner described hereinbefore. In all respects, excepting the substitution for the springs 63 of the retracted and a projected position; continuously ts acting means for urging and 'e'ifecti've'to move member connected to said barrier said barrier to the projected position, a crank shaft, means connecting said crank shaft to said barrier, said crank shaft serving to retract said barrier to the retracted position against the force of said continuously acting means, and means for locking said crank shaft in a position corresponding to the retracted position of said barrier.

2. In a protective system, a barrier, means for supporting said barrier for movement between a retracted and a projected position, continuously acting means for urging said barrier toward the projected position, a crank shaft, means including an arm connecting said crank shaft to said barrier by a lost motion connection, said crank shaft serving to retract said barrier to the retracted position against the force of such continuously acting means, and said lost motion connection serving to permit retraction of said barrier independently of the position of said crank shaft.

3. Inv a protective device, a barrier, means for supporting said barrier for movement between a retracted and a projected position, a crank shaft, means including an arm for forming a lost motion connection between said crank shaft and said barrier, said connection rendering said crank shaft effective to move said barrier from the projected to the retracted position, and additional means for urging said barrier toward the projected position.

4. In a protective system, a barrier, means for supporting said barrier for movement between a projected and a retracted position, continuously acting means acting between said barrier and said supporting means for moving said barrier toward the projected position, means including a drive for retracting said barrier to the retracted position against the force of said continuously acting means, and additional means actuated by said drive means for supplementing the effect of said continuously acting means to break said barrier loose from the retracted position. i

5. In a protective system, a barrier, means for supporting said barrier for movement between a projected and a retracted position, continuously acting means acting between said barrier and said supporting means for moving said barrier toward the projected position, means including a drive member connected to said barrier for retracting said barrier to the retracted position against the force of said continuously acting means, and means including a cam actuated by said drive means and coacting with said barrier to supplement the effect of said continuously acting means to break said barrier loose from the retracted position.

6. In a protective device, a barrier, means for supporting said barrier for movement between a retracted and a projected position, means acting on said barrier to urge and effective to move the same to the projected position, additional means acting on said barrier and effective to retract the same against the force of said first mentioned means, and locking means actuated by said additional means and effective to lock said barrier in the projected position.

'7. Ina protective system, a barrier, means for supporting said barrier for movement between a projected and a retracted position, continuously acting means for urging said barrier to the projected position, means including a drive shaft connected to said barrier for retractingsaid barmeans, and means including a swingable arm actuated by said drive shaft when said barrier approaches a projected position for movement into blocking relation to said barrier to lock the same in projected position.

8. In a protective system, a barrier, means for supporting said barrier for movement between a projected and a retracted position, continuously acting means for urging and effective to move said barrier to a projected position, means including a drive member having a lost motion connection with said barrier for retracting said barrier against the force of said continuously acting means, said lost motion connection permitting a retraction of said barrier independently of said drive means, and means including a snubber connected between said barrier and said supporting means for limiting the rate of rise of said barrier.

9. In a protective system, a selectively projectable and retractable barrier, a casing for supporting said barrier adapted to be imbedded in a roadway; means for pivotally mounting said barrier in said casing, including hinge mechanism disposed to resiliently oppose forces acting on said barrier; means including a plurality of weighted elements; a plurality of links for connecting said elements to said barrier to render a said elements efiective to continuously urge said barrier to the projected position; a crank shaft; a plurality of resiliently constructed arms forming a lost motion connection between said crank shaft and said barrier for rendering said crank shaft effective to retract said barrier against the force of said weighted elements, and for permitting a retracting movement of said barrier independentl of the position of said crank shaft; snubber mechanism acting between said barrier and said casing for limiting a projecting movement of said barrier; and control mechanism for said barrier including means to rotate said drive shaft and to lock said drive shaft in any one of a barrier to the retracted position and hold it in such retracted position against the force of said continuously acting means but enabling said barrier to be retracted independently of the position of said member, means for actuating said drive member, and a snubber connected between said barrier and said casing for limiting the rate of movement of said barrier in at least one direction.

11. In a protective device, a casing, a barrier, means for movably supporting said barrier in said casing for actuation from a retracted to a projected position, continuously acting means for applying a force to said barrier suflicient to move said barrier toward said projected position, a drive member mounted in said casing, connections between said member and said barrier enabling said member upon actuation to move said barrier to the retracted position and hold it in such retracted position against the force of said continuously acting means but enabling said barrier to be retracted independently of the position of said member, means for actuating said drive member, and a snubber connected between said barrier and said casing for limiting the rate of projecting movement of said barrier after a said independent retracting movement.

SU 0 NAMIEA. 

